Glass-molding machine



S. E. WINDER AND H. C. DAUBENSPECK.

Patented Feb. 24, 1920.

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S. E. WINDER AND H. C. DAUBENSPE I GLASS MOLDING MACHINE.

APPLICATION FILED APR. I5, I916- 1,331,792

S. E. WINDER AND H. C. DAUBENSPECK.

GLASS MOLDING MACHINE. APPLICATION FILED APR, 15, 1!?!6- Patented Feb. 24, 1920.

Patented Feb. 24,1920.

5 SHEETSSHEET 4.

S. E. WINDER AND H. C. DAUBENSPE GLASS MOLDING MACHINE. 4 APPLICATION FILED APR. 15, 1916. 1,331,792.

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S. E. WINDER AND H. C. DAUBENSPECK.

INE. ICATION FILED APR. 15, I916.

GLASS MOLDING MACH APPL Patented Feb. 24, 1920 5 SHEETS-SHEET 5.

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UNITED STATES PATENT OFFICE.

SAMUEL E. WINDER, OF CHICAGO, ILLINOIS, AND HENRY C. DAUBENSPECK, OF DUNKIRK, INDIANA.

GLASS-MOLDING MACHINE.

Application filed April 15,

To all whom it may concern:

Be it known that we, SAMUEL E. WINDER and HExnY C. DAUBENSPECK, citizens of the Fnited States. residing, respectively. at Chicago. in the county of Cook and State of Illinois, and Dunkirk, in the county of Jay and State of Indiana, have invented certain new and useful Improvements in Glass-Molding Machines, of which the following is a specification.

This invention relates to glass molding machines, and particularly to machines which are adapted to mold glass tumblers and the like.

One of the objects of the machine is to increase the rate at which the tumblers or other articles may be molded into shape. A. further object is to improve the quality of the molded article. A further object is to produce a machine for the purpose which will be more dependable and less likely to become inaccurate, particularly in reference to the registering of the various parts. Further objects of the invention will be apparent from a consideration of the accompanying drawings and the following description thereof:

Of the drawings, Figure 1 is a side elevation of a machine which embodies features of my invention. Fig. 2 is a plan View of the machine. Fig. 3 is a sectional elevation of the machine along the lines 33 of Fig. 2. Fig. l is a section along the line 11 of Fig. 2. Fig. 5 is an enlarged fragmental section along the line 55 of Fig. 1. Fig. 6 is an elevation of the mechanism for feeding the molten material to the machine. Fig. 7 is an enlarged plan view of one of the knives used in the mechanism for feeding the molten material. Fig. 8 is a section along the lines 8-8 of Fig. 7. Fig. 9 is a fragmental view showing the valve mechanism for operating the feeding mechanism. Fig. 10 is a section along the line 1010 of Fig. 9. Fig. 11 is an elevation of the mechanism provided to remove the molded tum+ blers from the mold. And Fig. 12 is an enlarged perspective view of a completed tumbler.

In general the machine which we have chosen to illustrate our invention comprises feeding mechanism for delivering molten glass in a proper manner to the molds of the molding machine. the inner surface of the molds corresponding to the outer sur- Specification of Letters Patent.

Patented Feb. 24, 1920.

1916. Serial No. 91,271.

faces of the tumblers to be molded; mechanism for transmitting the molds; a plunger, the outer surface of which corresponds to the inner surface of the tumbler to be molded; mechanism for forcing the plunger downwardly into the molds in successive order; mechanism for suitably removing the to the end of the walls of the conduit 15,

adjacent to the clay plate 18, which partly closes the end of the conduit, and through which is formed the outlet 16. Fixed to the frame 17, are uides 19, which allow a gate 20 to be slida ly mounted in front of the outlet 16. so that the magnitude of the outlet may be varied by varying the position of the gate. In order to suitably control the position of the gate, we provide a screw 21, which is connected at its lower end to the gate. The upper end of the screw is threaded into a bevel-gear '22 rotatably mounted in the frame; and this gear may be rotated by means of a hand wheel 23 journaled in brackets 24, fixed to the frame.

In operation, the molten mass of glass flows downwardly through the inclined outlet 16, which opens outwardly through the vertical end of the conduit. The molten mass then flows downwardly through the opening 30 inthe lower portion of the feeding mechanism. At the proper time the plastic mass of glass passing through this lower opening is cut ofl by knives in the following manner: The knives 31 and 32 are fixed in any suitable manner to holders 33 and 3i respectively. The holders are slida'bly mounted in the base 35 of the frame of the feeding mechanism, and are operatively connected wi h the driving mechanism in such a manner that, at the proper time, the knives will be moved toward each other against the stream flowing downwardly through the opening 30, and will meet at the central portion thereof and will thus disconnect the proper amount of the molten material from the flowing mass.

The mechanism for operating the knives comprises levers 36 pivoted to the frame at the points 37 and 38. The lower ends of these levers pass into recesses 43 and 44 in the knife holders, and the upper ends of the levers are connected by links 39 to a piston rod 40. The piston rod is operated by ,means of a piston 41, in the cylinder 42.

Any suitable means may be used for supplying compressed air or other gas to the cylinder 42 at the proper time. The means which I have used for this purpose are fully described hereinafter. When it is desired to operate the knives, compressed air is allowed to enter the upper end of the cylinder, and the downward movement of the piston resulting therefrom, by means of thelinks 39, forces outwardly the upper ends of the levers 36 and thus forces the knives inwardly.

The knives are so placed that the knife 31 passes over the knife 32; a projection 45, Fig. 8, with a beveled or rounded surface, being fixed to each knife, so as to properly guide the knives in their movement with reference to each other. Springs 46, 47, and 48 are fixed to the frame and tend to force the knives more closely together when they come in contact so as to produce a sharp cutting edge. In order to properly cool the knives, I have provided conduits 50 and 5-1 which are suitably connected to a source 0 water supply under pressure and to a suitable outlet for the water; so that water is continuously passing into the conduit 50 to a chamber 52 beneath the knife and out through the discharge conduit 51 (Fig. 7).

The molding machine receives the molten material from the feeding mechanism. The

molding machine is mounted upon a truckcomprising a floor 56, mounted on wheels 57, which runon T rails 58. Rotatably mountedon the floor of the truck is a mold table 59, the table being supported by a 'hub 60 rotatably mounted on ball-bearings 61 supported by the flange 62 of the center column 63.

When a suitable amount of molten material has been discharged from the feeding mechanism, the material isreceived by 'amold 55, which, at the proper time, is positioned about one inch below the opening 30. The molds 55, of which there are twelve, are supported by the table 59 and tently rotated thereby.

The following mechanism is provided for intermittentlyrotating the table, and hence the molds; so as to transmit the molds from the receiving to the molding position and from the moldin position to the ejecting position: 'Any sultable drivin means may e used for the purpose. In t is instance I have shown an electric motor 70, supported intermit-' on the floor of the trucks. The motor operates the main shaft 71, by means of the intermediate gear-wheels 72 and 73, shaft 74, and gear-wheels 75 and 76. Fixed to the shaft 71 is a bevel-gear 77 which meshes with a bevel-gear 78 fixedto the shaft 79. Fixed to the lower end of the shaft 79 is a crank 80, to which is pivotally connected a connecting bar 81. As the motor is operated, it is evident that, by means of this mechanism, the connecting bar 81 will be oscillated back and forth. This bar is pivoted to a bracket 82, fixed to a collar 83, which surrounds the hub 60, supporting the table 59; Slidably mounted in the bracket 82 is a pawl 84, which is yieldingly held, by means of a spring 85, against the periphery 86 of the flange 87 of the hub 60. Cut in the periphery of this flange are twelve equally spaced. notches 88 forming a pawl rack of the flange 87. The hub, and hence the table is thus rotated by means of the pawl 84 as the bar 81 is oscillated. The length of the crank is such that for each rotation of the shaft 79, the table is rotated through one-twelfth of a complete rotation or one notch of the pawl rack. In order to hold the table firmly in position when the movement thereof has been completed, a pin 90, slidably mounted in a frame 91 fixed to the truck, is adapted to pass into a notch 88 0f the rack, and is held firmly in place by means of the spring 92.

By these means suitable intermittent motion is given to the table, and hence, to the molds, and the molten material, when deposited in a mold, is transmitted away from the receiving position, and is properly positioned under a plunger. 100, which is arranged to mold the material into shape. The molding position of the mold with'reference to the receiving position is one-sixth of a rotation of the table. The mold containing the molten material is first removed from the receiving position by one-twelfth of a rotation of the table and it is there allowed to stand for a brief space of time in order to allow the material to settle properly in the mold. It is then transmitted by one-twelfth of a rotation of the table to the 116 molding position, as is indicated by Fig.3.

The mechanism for molding the glass, in addition to the molds, comprises the plunger 100 and means for suitably pressing the plunger into the molten mass in the mold, so 120 as to force the glass outwardly and upwardly between themold and the plunger in order to produce the shape desired. The means for operating the plunger consists of the following: Fixed to the main driving 126 shaft 71 is a pair of cam disks 101, having cam paths 102, in which are positioned the cam rollers 103, journaled to a beam 105. The lower end of the beam 105 is held in position by means of a slot 106 through which 130 passes the main driving shaft 71; the upper end of the beam is pivotally connected to the walking beam 107 pivoted at 108 to the housing 109, which is fixed to the fioor of the trucks; the other end of the walking beam is connected by connecting links 110 to' the cross-bar 111, slidably mounted on guide posts 112, which are supported by the frame of the machine by means of the supports 35. I

It will be seen that, by means of this mechanism, as the motor rotates, thus rotating the main drivin shaft 71 and the cam disks 101, the walking beam 108 will be oscillatedby means of the vertical beam 105, and the cross-head 111 will be reciprocated vertically on the guide posts 112. Fixed to the cross head 111 is a piston rod 113 having a thread at its upper end so that, by means of the nuts 114, its position with reference to the cross-head may be adjusted.

- By means of the rod 113, and other interme quantities of material in the mold. The

maximum pressure in all cases should besubstantially the same even though the mass of molten glass materially varies. We prefer to have the maximum pressure when the molding is being completed substantially sixty pounds per square inch; Evi

3 dently if the plunger were rigidly fixed to 45 the cross-head in each case the plunger would be moved downwardly exactly the same distance, so that if the amount of material were greater in one case than in another, the pressure thereon would become greater or means would need to be provided for removing .some of the material. We

have, therefore, found it desirable to provide means for varying slightly the position of the plunger at the end of the downward stroke, without varying the maximum pressure' thereon so as to compensate for varying masses of molten material, and at the same time maintaining the maximum pressure for an appreciable length of time, so as to allow the plastic material to properly set in form; and the means which we have provided for these purposes comprises the following:

Fixed to the lower end of the rod 113, is a piston 115, contained in a cylinder 116. The cyl1nder 116, by means of the rod 117 fixed thereto.

is fixed to the cross-head 128 and the plunger 100 is threaded into a plate 118 also fixed to the cross-head. -Hence, the connection between the plunger and the rod 113, is not rigid, but includes the piston 115 and the cylinder 116. Any suitable fluid may be introduced into the cylinder 116 beneath the piston. Wev prefer fo-r the pur-, pose compressed air, which may be supplied from any suitable source, such as a storage tank, having, in this particular instance, the constant pressure of substantially 30 pounds per square inch. In the pipe 120 which delivers the compressed air from the source to the cylinder 116, we provide some adjustable restricting means, such as the valve 121; so that, when the piston 115 is forced downwardly into the cylinder 116, the air contained in the cylinder will be at liberty topass back to the source through therestrioting means 121; but the rate of passage thereof will depend upon the degree of restriction in the pipe. As a consequence, when the plunger is' forced downwardly into the mold, the pressure will cause relative movement of the piston and cylinder and the air will be forced from the cylinder back through the pipe 120; but,

because of the restriction, the. pressure in the cylinder will be increased to an amount depending" upon the degree of restriction. The pressure will rise to a certain maximum amount, beyond which it will not go because, as the downward movement of the rod 113 is substantially constant, the air in the cylinder will escape at a constant rate when the maximum pressure is reached. By suit-ably adjusting the restriction and the pressure of the compressed air in the storage tank, the maximum pressure may be suitably predetermined at any desired amount.

In order to more properly complete the 'molding process, we provide a ring 125, en-

circling the plunger 100 and fixed to a plate 126. This plate is in turn fixed to pins 127, slidably mounted in the cross-bar 128 which is slidably supported by the posts, 112. Fixed to the bar 117, is a plate 129; and rods 130, fixed to the plate 126, pass freely through openings in the plate 129; and springs 131 encircle the rods and are compressed between the plates 126 and 129.- As the rod 117 is forced downwardly, it in turn forces downwardly, by means of the springs 131, the plate 126, and the plunger ring 125 The ring, before the plunger reaches its lowest position, is seated on the ring seat 132 and is pressed firmly thereon by means of the springs; 131, so that the glass is prevented from passing out from the mold, and the upper edge of the glass is pressed into suitable shape. As a consequence of this, it will be seen that any surplus amount of glass is retained in the mold, and the necessity arises for some constant oted to the lever 146,

pressure means, such as hereinabove described, acting on the plunger.

The instant the pressure on the glass reaches a certain predetermined amount, depending upon the material and the form of the vessel being molded, the pressure must be neither increased nor decreased for an appreciable length of time, as too great a pressure, or a reduction in pressure before the material had properly set, would produce an inferior article.

After the ring reaches its seat, the plunger continues to move downwardly a slight distance, and, as a consequence, when the plunger is forced upwardly, the ring 125 encircling the plunger moves downwardly with reference to the plunger and overcomes thus any tendency of the glass to adhere to the plunger. Suitable ordinary means, not shown, are used for keeping t-heplunger at the proper temperature.

When the molding of the tumbler has been completed, a litle time is required for it to cool so as to be sufficiently hard to handle. WVe, therefore, intermittently move the mold from the molding position to position 135, where the ejector removes, the glass from the mold. The ejector comprises the valve with the valve stem 66 and means for elevating the valve and stem at the proper time. These means comprise a frame 136 fixed to the floor of the trucks, in which, by means of guides 137, a lifter plate 138 is mounted for vertical movement. And mounted in the frame.

for horizontal movement is a cam plate 139. When the table is at rest, by means hereinaf'ter described, the cam plate 139 is moved from the position shown by the dotted lines in Fig. 11 to the position shown by the full lines. In this plate is a cam .slot 140, in which plays a cam roller 141 rotatably mounted on the lifter plate 138; and fixed to the lifter plate is a table 142, directly over which the stem 66 of the valve beneath the tumbler which is to be removed comes to rest. As the cam 'plateis moved from left to right, the table 142, and hence the valve, is elevated and carries with it the completed tumbler 143 which is to be removed, allowing it to be removed in any suitable manner.

The following means are provided for giving suitable movement to the cam plate 139: Pivoted to the bracket 82, which is reciprocated as the motor rotates in the manner hereinabove described, is a link 145, pivwhich is pivoted at 147 to the floor of the trucks. The other endof the lever 146 is connected, by means of a link148, to the bracket 82 is moving to the right, as shown in Fig. 5, in order to pass to another notch 88, the table will be held at rest by the pin cam plate 139.. As the 90; at the same time the cam plate 139 will be moved from its right-hand to its lefthand position, and table 142 will be elevated ejecting the tumbler from the mold. As the bracket moves to the left, moving with it the main table 59, the cam plate 139 will be moved to the right lowering the lifting table 142 for the reception of the next valve stem. But, as the table rotates toward the right, as indicated by the arrow in Fig. 1, carrying with it the elevated valve stem, the roller 141, playing on the upper horizontal portion 144, of the slot 140, will prevent downward movement of the table 142 until the elevated stem 66 passes on to the circular plate 150.; The plate 150 thus maintains in raised position the valve stem until the mold approaches the receiving position, when, by means of an inclined portion of the plate 150, indicated at 151, in Figs. 1 and 5, the stem and valve are lowered to normal position. By thus retaining the valve in'raised position its temperature is materially lowered.

We also provide means for supporting the edge of the table 59 under the molding mechanism as follows: A flange 155 projects downwardly from the periphery of the table. Under this flange, and positioned each side of the plunger mechanism, are rollers 156 supported by brackets 157, resting on wedges 158 and 159 supported by the floor of the trucks. By means of screws 160, relative movement of the wedges may be produced so as to vary the elevation of the rollers 156 and bring them snugly against the lower surface of the flange 155, thus firmly supporting the edge of the table in the neighborhood of the molding mechanism which comprise a cylinder 161 fixed to the provided also 115 trucks and havingtherein a piston fixed to the piston-rod 162, which is fixed rigidly to any suitable structure, such as the framework of the glass furnace. Connected to the source of supply of compressed air is a pipe 163, and connected to this pipe is an ordinary three-way valve 164, and pipes 165 lead therefrom to the ends of the cylinder. By suitably operating the valve, the trucks will be forced forwardly or backwardly, as

the case may be; and when the piston is i forced inwardly, so as to bring the machine 1 it will be into proper operating position,

means of firmly held in such position by the compressed air.

The means for operating the knives of the feeding mechanism comprises a valve 167, Figs. 9 and 10; the valve casing 170 which 1s fixed to the housing 109; a cam 168, fixed to the shaft 71; and a roller 169 rotatably mounted on the valve and operatively connecting the vali e with the cam. Connecting the valve with a source of compressed air is a pipe 171, which at all times allows the compressed air to pass freely into the valve chamber 176. This chamber provides a supply of compressed air in the valve so that the action of the air is accelerated. Connecting the valve with the respective ends of the cylinder 42 are pipes 172, 173, 17 4c and 175. Vhen the valve is in the position shown in Fig. 10, compressed air passes freely from the chamber 176 into the upper end of the cylinder, and the lower end of the cylinder is free to exhaust its air through pipe 172 and the exhaust port 177. As a consequence, the piston 41 is then forced down and the knives are closed. When closed the knives lap about three-eighths of an inch, so that a-complete smooth cut is made. When, as the shaft rotates, the roller approaches the annular portion of the cam,

the valve allows air to pass into the lower end of the cylinder and to exhaust from the upper end through port 178, and the knives are opened.

The complete operation of the machine is as follows: As the plunger 10O approaches its highest position, air begins to enter the upper end of the cylinder 12 to close the knives and just as the plunger reaches its highest position, as indicated in Fig. 3, the valve 167 reaches the full knife closing position, Fig. 10, and the lower portion of the stream of outflowing molten material pass ing into the mold beneath is instantly severed by the knives and sinks into the mold. At this same instant, the link 81, being in the position shown in Fig. 5, begins to rotate the mold table, and the mold containing the severed mass is moved to the next position. Although the knives are instantly returned to their normal positions, yet the outflowing stream, relieved of the downward pull of the severed mass, is retarded in its motion.

slightly allowing the next mold to pass under without striking the lower end of the stream. Thus the flow is continuous and the operation is as rapid as the nature of the mass will allow.

The mold is at rest under the opening 30 just long enough to properly receive the severed mass; it is then rotated to its position intermediate the receiving and the molding positions, and from this position it passes under the plunger. As the mold passes from the feeding mechanism to the molding mechanism the molten mass settles properly in the mold, ejecting any entrained air and cools to the most suitable temperature for molding. The plunger is then de pressed into the mass and the tumbler formed. At the same time, plate 142 is raised and the tumbler five steps ahead of the plunger is ejected, having had suflicient time to cool properly after being molded. Thus the receiving of the mass in the mold, the molding of a tumbler, and the eject-ing of another tumbler occur simultaneously, the knives closing just as the plunger rises to its highest point, and opening just as the of a second. so that the knives ofier no appreciable hindrance to the flow.

In the machines commonly used in practice for molding molten material into tumblers, cups are used into which the material passes from the outlet of the supply, and, when a suflic-ient quantity has accumulated, it is allowed to pass downwardly into the molds. This is frequently brought about, by having a slidable bottom to thecup, which is removed at the proper time. \Vhen mechanism of this nature is'used, it has been found that various disadvantages result: More time is required in order to allow the accumulation in the cup, as the molten material is not passing downwardly from the outlet in a substantially continuous stream and the distance from the outlet to the mold is necessarily materially greater than with our mechanism. As a consequence, the rate of operation is reduced, and the material becomes cooled to an undesirable extent. Also the weight of the material below the outlet, particularly as it passes into the mold from the cup, causes it to stretch the flowing massinto a small stream, so that as it passes into the mold it is stringy, and

more or less air is entrained in the mass in the mold some of which is held there until the molding process is completed. As a consequence of this, what are called laps are formed in the completed tumblers due to the surfaces of the molten mass becoming so cool that they do not properly weld together; and blisters are formed due to the entrained air. Also shear marks are formed in the tumblers, due to the special manner in which the molten stream is severed. As the false bottom of the cup acting as a cutter is passed under the cup, the edge of the cutter forces the molten mass to one side of the cup, leaving a sharp corner on the mass, which is not afterward sufficiently heated to cause it to weld properly with the other material.

By the use of the means which we have provided and hereinabove described, the

, rate of operation of the machine is materially increased, and the laps, blisters, and shear marks in the tumblers are materially reduced or entirely eliminated. As the molten mass is free to pass downwardly from the outlet directly into the mold, the .distance from the outlet to the mold is materially reduced. In practice, this distance is less than'one-half the distance with ordinary machines; being reduced some four inches by eliminating the cup hereinabove referred to. As a consequence, time is saved, and the stretching of the stream, due to the weight of the molten material, is very materiall reduced, and the material passes into the mold in a large stream that not only substantially excludes all the air, but

also maintains the temperature of the surfaces so high'that the welding is perfect and laps areprevented. Also as no air of con sequence is entrained, blisters are eliminated. At the same tlme, the lnstantaneo-us severing of the stream, and the cutting inwardly of' the two knives from opposite sides of the streams, leaves no cool edge on one side of the mass, so that the shear mark is eliminated.

From what has been said, it is evident that the speed of operation by the use of our machine may be greatly accelerated in practice. Machines ordinarily in use pro duce some fifteen tumblers per minute, while with the machine we have provided,'we are able to produce thirty tumblers per minute.

This, together with the elimination of' the disadvantages hereinabove referred to, results by carrying on the entire process while the condition of the molten mass is most suitable. The mass is" passed from the outlet to the mold in the most expeditious manner; the distance being as short as possible;

the stream being as large as is practicable, and the delay caused by the knives being reduced toa minimum.

It has been found in practice that the mold tables ordinarily in use expand and contract to such an extent as to cause inaccurate registering of the plunger and mold, and also, frequently, warping of the tables more or less. In order to avoid this, a part of our invention consists in placing a flange 155 around the periphery of the table 59, which acts not only as a stifiener for the table, but as a radiator therefor, so that the temperature of the table is materially reduced, and is maintained much more constant. This flange is made large, and hence.

table inside of the mold openings, thus giv- ,7

ing similarly increased radiating surface, increased cross-section for con-ducting the heat inwardly, and increased stiffening means. To further diminish the disadvantages arising from the over-heating of the table, We have mounted the molds on plates 180, supported by legs 181 which remove the molds a material distance away from the table, and, therefore, materially reduce the cross-section throiwh which the heat must pass to the table, t us assisting in reducing the temperature of the table and increasing the temperature of the mold, as in practice it is desirable not only to keep the table as cool as possible but also to keep the molds as hot as is possible by the ordinary opera tion of the machine.

Although we have described with considerable particularity the various details of the structure which we have selected to illustrate our invention, yet changes therein may be made by those familiar with the art without departing from the scope of our invention as disclosed by the following claims.

We claim as our invention:

1. In a glass molding machine, a mold, means for moving said mold, a valve positioned normally in'the bottom of said mold, and mechanical ejecting means for forcing said valve upwardly and ejecting the molded piece from said mold, said means comprising a slidable cam plate, a table positioned beneath the path of motion of said valve supported by said plate, and means for sliding said cam plate when said valve is over said table, and a valve stem passing downwardly from said valve through said mold, and. arranged to be operated by said table.

, 2. In a glass molding machine, a mold, a valve positioned normally in the bottom of said mold, and mechanical ejecting means for forcing said valve upwardly and ejecting'the molded piece from said mold, said means comprising a slidable cam plate, a table beneath said valve supported by said plate, means for sliding said cam plate, and means passing from said table to said valve.

In testimony whereof we hereunto set our hands.

Witnesses for Henry 0. P. MARTIN, ELMER E. SUTTON,

C. Daubenspeck: 

